EP0572438A1

EP0572438A1 - Contact element for a circuit-board relay, and a process for manufacturing such an element.

Info

Publication number: EP0572438A1
Application number: EP92903673A
Authority: EP
Inventors: Horst Hendel
Original assignee: Siemens AG
Current assignee: Siemens AG
Priority date: 1991-02-20
Filing date: 1992-02-05
Publication date: 1993-12-08
Anticipated expiration: 2012-02-05
Also published as: WO1992015107A1; US5426272A; DE59200860D1; ATE114868T1; JPH06505353A; CA2104384A1; DE4105288C2; DE4105288A1; EP0572438B1

Abstract

PCT No. PCT/DE92/00073 Sec. 371 Date Aug. 17, 1993 Sec. 102(e) Date Aug. 17, 1993 PCT Filed Nov. 2, 1993 PCT Pub. No. WO92/15107 PCT Pub. Date Sep. 3, 1992.The contact element (10) is formed from a round wire, this round wire being bent in the shape of a hairpin having two parallel limbs (11, 12), at least one of which is used as a soldering connecting pin. The curved region between the two pins is stamped flat to form a common contact zone (14) having a flat surface, and is provided with a contact piece. In consequence, heavy-current contacts can be constructed particularly favorably with printed-circuit board connections.

Description

Contact element for a circuit board relay and method for its production

The invention relates to a contact element for anchoring in a base body made of plastic for a relay, in particular a circuit board relay, this contact element forming a connecting pin with at least one end section. This is specifically a contact element which is suitable for carrying large currents and is anchored in a base or a base plate or in a pocket of a coil former. Furthermore, the invention also relates to a method for producing such a contact element.

Wire spring contacts are already known, for example from DE-OS 21 02 651. The wire springs used there, however, have a relatively thin cross-section, and both the movable contact elements and the mating contact elements are designed as long springs, which means that they have two springs the contact point and connecting pin result in a relatively high resistance, so that only low currents can be switched. This also results from the fact that the round spring cross sections lying crossed on top of one another in the contact area each result in only a point-like contact, which in turn means a high contact resistance and precludes the switching of large currents.

This also applies essentially to wire spring contacts, as are known from DE-AS 11 41 717. There, the contact points are strengthened in such a way that the ends of the wires are bent at the contact point and thus lie twice on top of one another. Nevertheless, there are point contacts between thin wire cross sections. Short round connecting pins with glass bushings in bases of hermetically sealed relays (DE-AS 16 15 838) are also known, but there the round connecting pin does not itself form the contact element, rather an additional contact spring element is welded there in the interior of the relay.

A relay is also known from US Pat. No. 3,624,571, in which contact elements movably arranged in the base have a round cross section and are flat-stamped at their contacting ends. However, this measure is not sufficient for carrying large currents.

Even with reed contacts, it is customary to provide the sections of the contact tongues melted into a glass tube with a round cross section, while the contact areas themselves are flattened. There, however, there are ferromagnetic tongues with relatively poor electrical conductivity, which also do not form any soldering pins with their connecting sections for insertion into a printed circuit board. In any case, such contact tongues would not be suitable for a relay for switching high currents.

Similar contact tongues are also shown in FR-OS 2 389 989, in each of which the end of a spring tongue is stamped and provided with a contact piece. There too, only the cross section of an elongated wire spring is available for the power line.

The problem with the contact elements considered here is that simple small relays for switching high currents, such as those used in motor vehicles, require counter-contact elements with large cross sections. These countercontact elements are generally cut from a flat strip material, flat plugs with the same or a similarly large rectangular cross section being formed on the connection side. If relays of this type are to be placed on printed circuit boards, it is customary to plug them in at the ends of the tabs Trimming to form short solder plugs that can be used in solder holes in the circuit board. Such solder holes in the printed circuit boards are drilled almost without exception to ensure that they have relatively smooth walls and are free from stress cracks. However, a soldering pin obtained by cutting a flat plug has a square or rectangular cross-section which does not completely fill the round hole, so that not only is part of the possible cross-section lost for the power line, but also the reliability of the connection on the printed circuit board is reduced.

With the invention, a contact element for a printed circuit board relay is to be created, which can be produced in the simplest way, with its connecting pins is adapted to the round printed circuit board bores and nevertheless enables large switching contact surfaces.

According to the invention, this object is achieved with the features of claim 1. In contrast to conventional contact springs made of round wire, a rigid mating contact element is created here, so that both the wire cross section and the wire material can be selected in accordance with the currents to be switched. Copper or a copper alloy is preferably used as the material. With their round cross section, the contact elements are not only well adapted to the holes in the printed circuit board, they can also be fastened well in corresponding holes or round openings in the base body by a press fit. This prevents, for example, rosin or other impurities from rising up into the contact space along the connection pins during the soldering process. In contrast to sharp-edged contact carriers, when round contact elements are plugged in there is no risk of abrasion and impairment of the insulating distances. By appropriate embossing, the pin ends can also be made burr-free. The hairpin shape with two parallel legs, at least one of which serves as a soldering pin, the area of curvature between the two legs forming a common contact zone with a flat surface results in an enlarged contact zone which can be provided with contact layers or with a weld contact . With two legs designed as connecting pins, there is also the double conductor cross section for carrying high currents between the switching contact and the printed circuit board. The two legs as connecting pins are arranged in a predetermined grid dimension so that they can be inserted into two adjacent bores of the circuit board and can be electrically connected to one another on the circuit board or in another circuit part.

An advantageous method for producing a contact element according to the invention provides that the wire is first bent in a U shape to form the two legs at a predetermined grid spacing and that the region of curvature is then stamped flat by means of an embossing device. Before the flat embossing, the two legs are bent in contact with one another in the region of the curvature. A contact piece is then expediently welded or brazed onto the contact zone.

Corresponding design of the embossing device or the embossing stamp allows depressions or raised portions to be molded onto the contact element. For example, warts for targeted welding or a guide groove can be stamped in as a plug-in aid. By limiting the embossing, the contact element can also be given dimensional fits in length and / or width. The flat stamping of the contact carrier also results in a space-saving arrangement when an additional contact piece is applied, since the contact piece on the embossed contact zone does not protrude beyond the diameter of the connecting pin. Due to the dimension of the flat embossing, a total height compensation of the contact surface can be achieved processing contacts of different heights. The leakage current behavior between two round contact elements is also improved compared to flat elements.

For an adequate plug-in fit in the base body, the connecting pins can be provided with retaining lugs which, for. B. when embossing the contact carrier or trimming the pins.

In a particularly advantageous embodiment of the manufacturing method, the contact carriers can be manufactured almost without waste. Here, the wire is bent in a meandering shape to form a band of connected, alternatingly opposing contact elements. The individual contact elements are then obtained by separation along the central axis of this band.

The invention is explained in more detail below using exemplary embodiments with reference to the drawing. Show it

FIG. 1 shows a schematic diagram of a relay with a base body, in which contact elements according to the invention are used,

FIG. 2 shows a single contact element with two legs in three views,

FIG. 3 shows a somewhat modified contact element in front view,

FIG. 4 shows an embossing device with a contact element in three views,

FIG. 5 shows a band of cohesively formed contact elements according to FIG. 2.

The relay shown in FIG. 1 has a customary design. construction with a coil body 1 serving as the base body, which is shown without winding. The magnet system of the relay is drawn schematically with a core 2, but 3 and an armature 4. With the armature 4, a contact spring 5 is actuated as a central contact spring, which has a strand connection 6, which is only partially drawn. In the base body 1, two counter-contact elements 10 are anchored in corresponding openings, each of which is flat-stamped in its upper regions 8 and each provided with a welded-on contact piece 9. The more precise design and manufacture of these contact elements 10 is explained in more detail with reference to the following figures.

FIG. 2 shows a contact element 10 which is bent like a hairpin from a round wire. The two legs 11 and 12 are formed with the round cross-section of the wire in parallel as solder pins at a predetermined distance according to a desired grid dimension. In the area of the curvature, however, the two legs are pressed together at point 13, forming a type of eyelet. In addition, this region of curvature is embossed flat and thus forms a contact zone 14 with flat surfaces, but less thick than the wire diameter. In Figure 2, the contours of the wire after bending and before the flat stamping are indicated with the dashed lines 15, while the solid lines 16 represent the contours of the finished contact element. In the central region of the contact zone 14, a circular welding region 17 is embossed. This results in a good welding surface for a subsequently applied contact piece 18, which is not shown in the front view of FIG . On the upper side of the contact zone 14, an end face 20 is stamped by appropriate design of the embossing tool, as a result of which the contact element as a whole is given a predetermined length. As can also be seen in FIG. 2, a guide groove 21 can be stamped into the rear of the contact zone as a plug-in aid. Depending on the requirements of the contact position, the area of curvature of the contact element with the contact zone formed from it can either be designed symmetrically to the two legs 11 and 12, as shown in FIG. 2, or it can also be designed asymmetrically. FIG. 3 shows one possibility for the latter design, the contact area being designed to be inclined at an angle of, for example, 45 ^* to the longitudinal axis of the legs 11 and 12. In this case, not only is an end surface 20 embossed on the upper side, but also a side end surface 22 is stamped on the right in the drawing, as a result of which the contact element assumes a predetermined fit both in length and in width.

4 shows the shape of the contact element in an embossing tool. This tool consists of an embossing receptacle 23 with an embossing recess 24 which defines the fit or the limits of the contact element and an embossing stamp 25 which is not shown in the top view of FIG. 7. The contact element 10 or the pre-bent wire 26 is inserted into the embossing receptacle 23 and then embossed into the corresponding shape with the embossing stamp 25, the contact tongue 14 in particular being embossed from the original contour 15 into the contour 16. For this purpose, the embossed receptacle 23 has an elevation 27, in which a recess 28 is provided to form the welding region 17 mentioned. Before that, however, the area of curvature is embossed on contact by means of lateral embossing dies which are introduced in the direction of the arrows 29.

The manufacturing method is particularly advantageous when not every individual contact element is bent and. is embossed, but a plurality of contact elements can be formed in an endless production from a continuous wire. FIG. 5 shows a section of a continuous band 30 of contact elements 10, which are formed contiguously by a wire 26 in the form of a serpentine bend. The individual contact elements 10 can, for example, bundle tools are successively embossed on the form and provided with contact pieces. Only the finished contact elements 10 are then obtained by removing the middle pieces 31 along the central axis of the band 30.

Claims

1. Contact element for anchoring in a base body (1) made of plastic for relays with the following features: - The contact element (10) is formed in one piece from a round wire as a rigid counter contact

- It is curved in a hairpin shape with two parallel legs (11, 12), at least one of which serves as a connecting pin; - The two legs (11, 12), which run parallel and at a predetermined distance, are bent in contact with one another in the region of curvature and

- The area of curvature between the two legs (11, 12) is embossed flat to a common contact zone (14) with a flat surface and covered with a contact layer (18).

2. Contact element according to claim 1, wherein the contact zone (14) with respect to the longitudinal axis of the legs (11, 12) is inclined (Figure 3).

3. Contact element according to claim 1 or 2, wherein the contact zone (14) is covered at least on one side with a preferably welded contact piece (18).

4. Contact element according to one of claims 1 to 3, wherein the legs (11, 12) are each provided in the areas intended for anchoring in the carrier (1) with stamped retaining lugs.

5. A method for producing a contact element according to one of claims 1 to 4, wherein first a round wire (26) is U-shaped to form the two legs (11, 12) at a predetermined grid spacing, the two Legs (11, 12) are bent in the region of the curvature upon contact with one another and the curvature region is finally embossed by means of an embossing device (23, 25).

6. The method according to claim 5, wherein an er¬ welding area (17) is impressed on the contact zone.

7. The method according to claim 5, wherein by meandering bending of the wire (26) a band (30) of coherent, alternatingly opposing contact elements (10) is formed ge, and wherein by separating along the central axis of the band individual contact elements can be obtained.